Expression of a xylanase gene of Bacillus pumilus in Escherichia coli and Bacillus subtilis

Summary A hybrid plasmid, pOXN29 (10.4 Mdal), coding the xylanase (xynA) and -xylosidase (xynB) genes of Bacillus pumilus IPO was constructed by the ligation of pBR322 and a 7.7 Mdal PstI-fragment of chromosomal DNA as reported in our previous paper (Panbangred et al. 1983). A deletion plasmid of pOXN29, pOXN293 (9.2 Mdal), which contains xynA and xynB, was ligated with pUB110 at an EcoRI site, and used to transform B. subtilis MI111. Two selected clones of B. subtilis as xylanase hyper-producers contained plasmids pOXW11 (4.2 Mdal) and pOXW12 (4.0 Mdal), both consisting of only pUB110, xynA, and its flanking regions, as the result of spontaneous deletion. These B. subtilis clones produced 2.7–3.0 times as much xylanase as B. pumilus. Escherichia coli and B. subtilis clones harbouring the hybrid plasmids synthesized xylanase and -xylosidase constitutively, whereas both enzymes were induced by xylose in B. pumilus.Xylanase synthesized by B. subtilis harbouring pOXW11 or pOXW12 was excreted into the medium like that of B. pumilus IPO, but xylanase synthesized in E. coli harbouring pOXN29, 293 or pOXW1 coding xynA was intracellular. In a previous investigation (Panbangred et al. 1983), xylanase was found to be located in the cytoplasm, not the periplasm nor the membrane fraction in E. coli cells harbouring pOXN29 derivatives. In spite of the abnormal location of xylanase synthesized in E. coli, the signal peptide was processed in the same way as in B. pumilus, with the same molecular weight and the same amino terminal sequences of xylanase prepared from E. coli cells and B. pumilus culture fluid.     

Molecular cloning of the genes for xylan degradation of Bacillus pumilus and their expression in Escherichia coli

Summary The 7.7 Mdal PstI fragment of Bacillus pumilus IPO containing genes for xylan degradation, xylanase, and -xylosidase was inserted at the PstI site of pBR322 and cloned in E. coli C600. The hybrid plasmid thus formed was named pOXN29. The amount of xylanase and -xylosidase expressed in E. coli harboring pOXN29 was about 6% and 20% of the activity produced by the donor, B. pumilus. The reverse orientation of the inserted fragment resulted respectively in 5 times and 50 times increases in xylanase and -xylosidase productivities. Both enzymes expressed in E. coli transformants were shown to be indistinguishable from those of B. pumilus by immunological and chemical criteria. Digestion of pOXN29 with BglII produced two fragments; one was 6.7 Mdal in size and contained the whole pBR322 and the -xylosidase gene, and the other was 3.7 Mdal and coded for xylanase. Analysis of enzymes expressed in the transformant cells indicated that neither enzyme was secreted into the culture medium, periplasm nor membrane bound, although xylanase but not -xylosidase, was secreted into the medium in a B. pumilus culture.     

Distribution and Evolution of the Xylanase Genes xynA and xynB and Their Homologues in Strains of Butyrivibrio fibrisolvens

The ruminal bacterium Butyrivibrio fibrisolvens is being engineered by the introduction of heterologous xylanase genes in an attempt to improve the utilization of plant material in ruminants. However, relatively little is known about the diversity and distribution of the native xylanase genes in strains of B. fibrisolvens. In order to identify the most appropriate hosts for such modifications, the xylanase genotypes of 28 strains from the three 16S ribosomal DNA (rDNA) subgroups of Butyrivibrio fibrisolvens have been investigated. Only 4 of the 20 strains from 16S rDNA group 2 contained homologues of the strain Bu49 xynA gene. However, these four xynA-containing strains, and two other group 2 strains, contained members of a second xylanase gene family clearly related to xynA (subfamily I). Homologues of xynB, a second previously described xylanase gene from B. fibrisolvens, were identified only in three of the seven group 1 strains and not in the group 2 and 3 strains. However, six of the group 1 strains contained one or more members of the two subfamilies of homologues of xynA. The distribution of genes and the nucleotide sequence relationships between the members of the two xynA subfamilies are consistent with the progenitor of all strains of B. fibrisolvens having contained a xynA subfamily I gene. Since many xylanolytic strains of B. fibrisolvens did not contain members of either of the xynA subfamilies or of the xynB family, at least one additional xylanase gene family remains to be identified in B. fibrisolvens.     

Cloning, expression and nucleotide sequences of two xylanase genes from Paenibacillus sp.

Two genes, xynA and xynB, encoding xylanases from Paenibacillus sp. KCTC 8848P were cloned and expressed in Escherichia coli, and their nucleotide sequences were determined. The xylanases of E. coli transformants were released into the extracellular culture fluid in the absence of xylan. The structural gene of xynA 636 bp, encoded a protein of 212 amino acids, while the xynB gene consisted of 951 bp open reading frame for a protein of 317 amino acids. The amino acid sequence of the xynAgene showed 83% similarity to the xylanase of Aeromonas caviae, and belonged to the family 11 glycosyl hydrolases. The deduced amino acid sequence of the xynB gene, however, showed 51% similarity to the xylanase of Rhodothermus marinus, and belonged to the family 10 glycosyl hydrolases.     

Family 10 and 11 xylanase genes from Caldicellulosiruptor sp. strain Rt69B.1

Three family 10 xylanase genes (xynA, xynB, and xynC) and a single family 11 xylanase gene (xynD) were identified from the extreme thermophile Caldicellulosiruptor strain Rt69B.1 through the use of consensus PCR in conjunction with sequencing and polyacrylamide gel electrophoresis. These genes appear to comprise the complete endoxylanase system of Rt69B.1. The xynA gene was found to be homologous to the xynA gene of the closely related Caldicellulosiruptor strain Rt8B.4, and primers designed previously to amplify the Rt8B.4 xynA gene could amplify homologous full-length xynA gene fragments from Rt69B.1. The complete nucleotide sequences of the Rt69B.1 xynB, xynC, and xynD genes were obtained using genomic walking PCR. The full-length xynB and xynC genes are more than 5 kb in length and encode highly modular enzymes that are the largest xylanases reported to date. XynB has an architecture similar to the family 10 xylanases from Thermoanaerobacterium saccharolyticum (XynA) and Clostridium thermocellum (XynX) and may be cell wall associated, while XynC is a bifunctional enzyme with an architecture similar to the bifunctional β-glycanases from Caldicellulosiruptor saccharolyticus. The xynD gene encodes a two-domain family 11 xylanase that is identical in architecture to the XynB family 11 xylanase from the unrelated extreme thermophile Dictyoglomus thermophilum strain Rt46B.1. The sequence similarities between the Rt69B.1 xylanases with respect to their evolution are discussed. Received: May 13, 1998 / Accepted: October 22, 1998     

Production of a bacterial thermophilic xylanase inSaccharomyces cerevisiae

ThexynA gene (encoding xylanase) from the obligately anaerobic thermophilic bacteriumCaldocellum saccharolyticum has been inserted into the yeast expression vector, pFLAGU2. Yeast cells containing this vector were able to produce and secrete active xylanase into the growth medium. Xylanase was purified by the use of an affinity column specific for a rare peptide sequence fused to the N-terminus of the xylanase. Sodium dodecyl sulphate-polyacrylamide gel electrophoresis of the purified fractions revealed that the enzyme had been fortuitously glycosylated. The specific activity of the purified xylanase was found to be 90 international units/mg protein. The amount of xylanase secreted into the surrounding medium was approximately 10 mg/l.     

Optimization of nutrient medium containing agricultural waste for xylanase production by Bacillus pumilus B20

We aimed to optimize a nutrient medium containing agricultural waste for xylanase production by Bacillus pumilus B20. Xylanase production with lignocellulosic material was optimized in two steps using DeMeo’s fractional factorial design. A 3.4-fold increase in xylanase production (313.3 U/mL) was achieved using the optimized culture medium consisting of (g/L): K₂HPO₄, 2; MgSO₄·7H₂O, 0.3; CaCl₂·2H₂O, 0.01; NaCl, 2; peptone, 5 yeast extract, 4; and wheat bran, 50. _{B. pumilus} B20 produced a high level of xylanase, which may have potential industrial application.     

Simultaneous secretion of seven lignocellulolytic enzymes by an industrial second-generation yeast strain enables efficient ethanol production from multiple polymeric substrates

A major hurdle in the production of bioethanol with second-generation feedstocks is the high cost of the enzymes for saccharification of the lignocellulosic biomass into fermentable sugars. Simultaneous saccharification and fermentation with Saccharomyces cerevisiae yeast that secretes a range of lignocellulolytic enzymes might address this problem, ideally leading to consolidated bioprocessing. However, it has been unclear how many enzymes can be secreted simultaneously and what the consequences would be on the C6 and C5 sugar fermentation performance and robustness of the second-generation yeast strain. We have successfully expressed seven secreted lignocellulolytic enzymes, namely endoglucanase, β-glucosidase, cellobiohydrolase I and II, xylanase, β-xylosidase and acetylxylan esterase, in a single second-generation industrial S. cerevisiae strain, reaching 94.5 FPU/g CDW and enabling direct conversion of lignocellulosic substrates into ethanol without preceding enzyme treatment. Neither glucose nor the engineered xylose fermentation were significantly affected by the heterologous enzyme secretion. This strain can therefore serve as a promising industrial platform strain for development of yeast cell factories that can significantly reduce the enzyme cost for saccharification of lignocellulosic feedstocks.     

β-xylosidases and a nonspecific wall-bound β-glucosidase of the yeast cryptococcus albidus

Cryptococcus albidus grown on wood xylans possesses a soluble intracellular β-xylosidase (EC 3.2.1.37) as an additional constituent of the xylan-degrading enzyme system of this yeast. The enzyme attacks linear 1,4-β-xylooligosaccharides in an exo-fashion, liberating xylose from the non-reducing ends. The activity of the enzyme increases in the cells during growth on xylan and incubation with xylobiose or methyl β-D-xylopyranoside which are the best inducers of extracellular β-xylanase (EC 3.2.1.8). Various alkyl-, alkyl-1-thio- and aryl β-D-xylopyranosides were excellent of a different β-xylosidase of Cryptococcus albidus. This enzyme is localized outside the plasma membrane and is principally associated with cell walls. Unlike the soluble intracellular β-xylosidase, the wall-bound enzyme does not hydrolyze xylooligosaccharides. Evidence has been obtained that β-xylosidase activity in the cell walls is not due to the presence of a specific aryl β-xylosidase, but is exhibited by a nonspecific β-glucosidase (EC 3.2.1.21) inducible by β-D-xylopyranosides. The ratio of β-glucosidase and β-xylosidase activity in the cells and isolated cell walls from yeast induced by various β-xylopyranosides and β-glucopyranosides was very similar. Both wall-bound activities were inhibited in a similar pattern by inhibitors of β-glucosidases, 1,5-gluconolactone and nojirimycin. This bifunctional enzyme does not bear any relationship to the utilization of xylans in Cryptococcus albidus.     

Cloning of the Bacillus pumilusβ-xylosidase gene (xynB ) and its expression in Saccharomyces cerevisiae

A genomic DNA library of the bacterium Bacillus pumilus PLS was constructed and the β-xylosidase gene (xynB) was amplified from a 3-kb genomic DNA fragment with the aid of the polymerase chain reaction technique. The amplified xynB gene was inserted between the yeast alcohol dehydrogenase II gene promoter (ADH2 _P ) and terminator (ADH2 _T ) sequences on a multicopy episomal plasmid (pDLG11). The xynB gene was also fused in-frame to the secretion signal sequence of the yeast mating pheromone α-factor (MFα1 _S ) before insertion between the ADH2 _P and ADH2 _T sequences on a similar multicopy episomal plasmid (pDLG12). The resulting construct ADH2 _P -MFα1 _S -xynB-ADH2 _T was designated XLO1. Both plasmids pDLG11 and pDLG12 were introduced into Saccharomyces cerevisiae but only the expression of the XLO1 gene yielded biologically functional β-xylosidase. The total β-xylosidase activity remained cell-associated with a maximum activity of 0.09 nkat/ml obtained when the recombinant S. cerevisiae strain was grown for 143 h in synthetic medium. The temperature and pH optima of the recombinant Xlo1 enzyme were 45–50 °C and pH 6.6 respectively. The enzyme was thermostable at 45 °C; however, at 60 °C most of the Xlo1 was inactive after 5 min. Received: 11 July 1996 / Received revision: 23 October 1996 / Accepted: 25 October 1996     

Xylanase from a soil isolate, <Emphasis Type="Italic">Bacillus pumilus</Emphasis>: gene isolation,enzyme production,purification, characterization and one-step separation by aqueous-two-phase system

A xylanase producer, Bacillus pumilus SB-M13, was isolated from soil and identified using various tests based on carbohydrate fermentation preferences and fatty acid analysis. Xylanase gene, isolated using PCR amplification, was partially sequenced and it showed 89–94% sequence similarity to the xylanase genes of other B. pumilus strains. Xylanase with very low level of cellulase was produced on agricultural byproducts. The enzyme has been purified 186-fold by hydrophobic interaction chromatography and biochemically characterized. It has a molecular weight of 24.8 kDa and pI of 9.2. Xylanolytic activity is stable at alkaline pH and highest activity is observed at 60 °C and pH 7.5. Enzyme K _m and k _cat values were determined as 1.9 mg/mL and 42,600 U/mg, respectively. In aqueous-two-phase system, xylanase always partitioned to the top phase. Basic pH, low PEG concentration, salt addition, and presence of microbial cells enhanced xylanase partitioning. A maximum sevenfold purification, 10-fold concentration and 100% xylanase recovery were obtained, separately, by adjusting system parameters. A fourfold concentrated xylanase was obtained with 70% enzyme recovery only in one step ATPS process without cell harvesting.     

Construction of a Xylan-Fermenting Yeast Strain through Codisplay of Xylanolytic Enzymes on the Surface of Xylose-Utilizing Saccharomyces cerevisiae Cells

Hemicellulose is one of the major forms of biomass in lignocellulose, and its essential component is xylan. We used a cell surface engineering system based on α-agglutinin to construct a Saccharomyces cerevisiae yeast strain codisplaying two types of xylan-degrading enzymes, namely, xylanase II (XYNII) from Trichoderma reesei QM9414 and β-xylosidase (XylA) from Aspergillus oryzae NiaD300, on the cell surface. In a high-performance liquid chromatography analysis, xylose was detected as the main product of the yeast strain codisplaying XYNII and XylA, while xylobiose and xylotriose were detected as the main products of a yeast strain displaying XYNII on the cell surface. These results indicate that xylan is sequentially hydrolyzed to xylose by the codisplayed XYNII and XylA. In a further step toward achieving the simultaneous saccharification and fermentation of xylan, a xylan-utilizing S. cerevisiae strain was constructed by codisplaying XYNII and XylA and introducing genes for xylose utilization, namely, those encoding xylose reductase and xylitol dehydrogenase from Pichia stipitis and xylulokinase from S. cerevisiae. After 62 h of fermentation, 7.1 g of ethanol per liter was directly produced from birchwood xylan, and the yield in terms of grams of ethanol per gram of carbohydrate consumed was 0.30 g/g. These results demonstrate that the direct conversion of xylan to ethanol is accomplished by the xylan-utilizing S. cerevisiae strain.     

Nucleotide sequences of two contiguous and highly homologous xylanase genes xynA and xynB and characterization of XynA from Clostridium thermocellum

A 5.7-kbp region of the Clostridium thermocellum F1 DNA was sequenced and found to contain two contiguous and highly homologous xylanase genes, xynA and xynB. The xynA gene encoding the xylanase XynA consists of 2049 bp and encodes a protein of 683 amino acids with a molecular mass of 74 511 Da, and the xynB gene encoding the xylanase XynB consists of 1371 bp and encodes a protein of 457 amino acids with a molecular mass of 49 883 Da. XynA is a modular enzyme composed of a typical N-terminal signal peptide and four domains in the following order: a family-11 xylanase domain, a family-VI cellulose-binding domain, a dockerin domain, and a NodB domain. XynB exhibited extremely high overall sequence homology with XynA (identity 96.9%), while lacking the NodB domain present in the latter. These facts suggested that the xynA and xynB genes originated from a common ancestral gene through gene duplication. XynA was purified from a recombinant Escherichia coli strain and characterized. The purified enzyme was highly active toward xylan; the specific activity on oat-spelt xylan was 689 units/mg protein. Immunological and zymogram analyses suggested that XynA and XynB are components of the C. thermocellum F1 cellulosome. Received: 21 September 1998 / Received revision: 30 October 1998 / Accepted: 29 November 1998     

Identification and characterisation of xylanolytic yeasts isolated from decaying wood and sugarcane bagasse in Brazil

In this study, yeasts associated with lignocellulosic materials in Brazil, including decaying wood and sugarcane bagasse, were isolated, and their ability to produce xylanolytic enzymes was investigated. A total of 358 yeast isolates were obtained, with 198 strains isolated from decaying wood and 160 strains isolated from decaying sugarcane bagasse samples. Seventy-five isolates possessed xylanase activity in solid medium and were identified as belonging to nine species: Candida intermedia, C. tropicalis, Meyerozyma guilliermondii, Scheffersomyces shehatae, Sugiyamaella smithiae, Cryptococcus diffluens, Cr. heveanensis, Cr. laurentii and Trichosporon mycotoxinivorans. Twenty-one isolates were further screened for total xylanase activity in liquid medium with xylan, and five xylanolytic yeasts were selected for further characterization, which included quantitative analysis of growth in xylan and xylose and xylanase and β-d-xylosidase activities. The yeasts showing the highest growth rate and cell density in xylan, Cr. laurentii UFMG-HB-48, Su. smithiae UFMG-HM-80.1 and Sc. shehatae UFMG-HM-9.1a, were, simultaneously, those exhibiting higher xylanase activity. Xylan induced the highest level of (extracellular) xylanase activity in Cr. laurentii UFMG-HB-48 and the highest level of (intracellular, extracellular and membrane-associated) β-d-xylosidase activity in Su. smithiae UFMG-HM-80.1. Also, significant β-d-xylosidase levels were detected in xylan-induced cultures of Cr. laurentii UFMG-HB-48 and Sc. shehatae UFMG-HM-9.1a, mainly in extracellular and intracellular spaces, respectively. Under xylose induction, Cr. laurentii UFMG-HB-48 showed the highest intracellular β-d-xylosidase activity among all the yeast tested. C. tropicalis UFMG-HB 93a showed its higher (intracellular) β-d-xylosidase activity under xylose induction and higher at 30 °C than at 50 °C. This study revealed different xylanolytic abilities and strategies in yeasts to metabolise xylan and/or its hydrolysis products (xylo-oligosaccharides and xylose). Xylanolytic yeasts are able to secrete xylanolytic enzymes mainly when induced by xylan and present different strategies (intra- and/or extracellular hydrolysis) for the metabolism of xylo-oligosaccharides. Some of the unique xylanolytic traits identified here should be further explored for their applicability in specific biotechnological processes.     

Cloning of the xynB Gene from Dictyoglomus thermophilum Rt46B.1 and Action of the Gene Product on Kraft Pulp

A two-step PCR protocol was used to identify and sequence a family 11 xylanase gene from Dictyoglomus thermophilum Rt46B.1. Family 11 xylanase consensus fragments (GXCFs) were amplified from Rt46B.1 genomic DNA by using different sets of consensus PCR primers that exhibited broad specificity for conserved motifs within fungal and/or bacterial family 11 xylanase genes. On the basis of the sequences of a representative sample of the GXCFs a single family 11 xylanase gene (xynB) was identified. The entire gene sequence was obtained in the second step by using genomic walking PCR to amplify Rt46B.1 genomic DNA fragments upstream and downstream of the xynB GXCF region. The putative XynB peptide (M_r, 39,800) encoded by the Rt46B.1 xynB open reading frame was a multidomain enzyme comprising an N-terminal catalytic domain (M_r, 22,000) and a possible C-terminal substrate-binding domain (M_r, 13,000) that were separated by a short serine-glycine-rich 23-amino-acid linker peptide. Seven xylanases which differed at their N and C termini were produced from different xynB expression plasmids. All seven xylanases exhibited optimum activity at pH 6.5. However, the temperature optima of the XynB xylanases varied from 70 to 85°C. Pretreatment of Pinus radiata and eucalypt kraft-oxygen pulps with XynB resulted in moderate xylan solubilization and a substantial improvement in the bleachability of these pulps.     

Molecular Cloning and Expression of a Xylanase Gene from Bacillus polymyxa in Escherichia coli

Genomic fragments of Bacillus polymyxa derived from separate and complete digestion by EcoRI, HindIII, and BamHI were ligated into the corresponding sites of pBR322, and the resulting chimeric plasmids were transformed into Escherichia coli. Of 6,000 transformants screened, 1 (pBPX-277) produced a clear halo on Remazol brilliant blue xylan plates. The insert in the pBPX-277 recombinant, identified as an 8.0-kilobase BamHI fragment of B. polymyxa, was subsequently subjected to extensive mapping and a series of subclonings into pUC19. A 2.9-kilobase BamHI-EcoRI subfragment was found to code for xylanase activity. Xylanase activity expressed by E. coli harboring the cloned gene was located primarily in the periplasm and corresponded to one of two distinct xylanases produced by B. polymyxa. Xylanase expression by the cloned gene occurred in the absence of xylan and was reduced by glucose and xylose. Southern blot hybridization with the cloned fragment as a probe against complete genomic digests of the bacilli B. polymyxa, B. circulans, and B. subtilis revealed that the cloned xylanase gene was unique to B. polymyxa. The xylanase expressed by the cloned gene had a molecular weight of approximately 48,000 and an isoelectric point of 4.9.     

Evaluation of different microbial xylanolytic systems

The xylanolytic enzymes produced by Trichoderma reesei QM 9414, Aspergillus awamori VTT-D-75028, Fusarium oxysporum VTT-D-80134, Bacillus subtilis ATCC 12711 and Streptomyces olivochromogenes ATCC 21713 differed with respect to β-xylosidase activity and side-group cleaving activities. The highest xylanase activity was produced by T. reesei. All the fungi produced β-xylosidase, whereas in the bacterial culture filtrates β-xylosidase activity was negligible. T. reesei culture filtrate contained all the side-group cleaving activities assayed (acetyl esterase, α-glucuronidase and α-arabinosidase) and those of F. oxysporum and S. olivochromogenes contained esterase. All the side-group cleaving activities were low in the culture filtrates of A. awamori and B. subtilis.The differences between the xylanolytic systems were reflected in the hydrolysis of steamed birchwood hemicellulose. The xylose yields obtained ranged from 0 (with B. subtilis) to 90% (with T. reesei) of the theoretical maximum. The best enzyme for complete hemicellulose hydrolysis was therefore that of T. reesei. However, in some applications in which complete hydrolysis is not needed or in which hydrolysis of cellulose is to be avoided, one of the other xylanases may be more suitable than that of T. reesei.     

Cost-effective and concurrent production of industrially valuable xylano-pectinolytic enzymes by a bacterial isolate Bacillus pumilus AJK

Simultaneous production of xylanase and pectinase by Bacillus pumilus AJK under submerged fermentation was investigated in this study. Under optimized conditions, it produced 315?±?16 IU/mL acidic xylanase, 290?±?20 IU/mL alkaline xylanase, and 88?±?9 IU/mL pectinase. The production of xylano-pectinolytic enzymes was the highest after inoculating media (containing 2% each of wheat bran and Citrus limetta peel, 0.5% peptone, 10?mM MgSO₄, pH 7.0) with 2% of 21-hr-old culture and incubated at 37°C for 60?hr at 200?rpm. Xylanase retained 100% activity from pH 6.0 to10.0 after 3?hr of incubation, while pectinase showed 100% stability from pH 6.0 to 9.0 even after 6?hr of incubation. Cost-effective and concurrent production of xylanase and pectinase by a bacterial isolate in the same production media suggests its potential for various biotechnological applications. This is the first report of simultaneous production of industrially important extracellular xylano-pectinolytic enzymes by B. pumilus.     

Production of xylanase and β-xylosidase from autohydrolysis liquor of corncob using two fungal strains

Agroindustrial residues are materials often rich in cellulose and hemicellulose. The use of these substrates for the microbial production of enzymes of industrial interest is mainly due to their high availability associated with their low cost. In this work, corncob (CCs) particles decomposed to soluble compounds (liquor) were incorporated in the microbial growth medium through autohydrolysis, as a strategy to increase and undervalue xylanase and β-xylosidase production by Aspergillus terricola and Aspergillus ochraceus. The CCs autohydrolysis liquor produced at 200 °C for 5, 15, 30 or 50 min was used as the sole carbon source or associated with untreated CC. The best condition for enzyme synthesis was observed with CCs submitted to 30 min of autohydrolysis. The enzymatic production with untreated CCs plus CC liquor was higher than with birchwood xylan for both microorganisms. A. terricola produced 750 total U of xylanase (144 h cultivation) and 30 total U of β-xylosidase (96-168 h) with 0.75% untreated CCs and 6% CCs liquor, against 650 total U of xylanase and 2 total U of β-xylosidase in xylan; A. ochraceus produced 605 total U of xylanase and 56 total U of β-xylosidase (168 h cultivation) with 1% untreated CCs and 10% CCs liquor against 400 total U of xylanase and 38 total U of β-xylosidase in xylan. These results indicate that the treatment of agroindustrial wastes through autohydrolysis can be a viable strategy in the production of high levels of xylanolytic enzymes.